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Transcript
Friedreich Ataxia: Update
April 1, 2016
David R. Lynch, MD PhD
Friedreich Ataxia (FA)
• Nicolaus Friedreich first described in
1860’s based on 6 patients from 2
families
• A rare, genetic condition that is a
progressive degenerative disease of
children, adolescents and adults
• Affects 1 in 50,000
• Estimated 5-6,000 individuals in US
and 10-15,000 worldwide
• Typically thought of as a
neurodegenerative disease as this is
the most visible and common
symptom; however FA is a multisystem disease
FA – Clinical Features
Clinical features: Neuro
• Loss of large sensory neurons - proprioception
• Loss of balance and coordination
• Loss of reflexes
• Loss of spinocerebellar tracts
• Loss of balance and coordination
• Loss of motor tracts to a lesser degree
• Loss of dentate nucleus of the cerebellum
• Dysarthria (slurred speech), modest eye movement
abnormalities
• Loss of a few other specific sites
• Vision, hearing loss
• Sparing of cerebellar cortex, cerebral cortex
• Normal cognition
• Overall loss of relatively few neurons, modest number of
axonal tracts----MRI scans are normal or almost normal in
FA – Clinical Features
• Heart: Cardiomyopathy and arrhythmia
• Hypertrophic cardiomyopathy
• Later onset of progressive cardiac fibrosis
with loss of systolic function
• Clinically insignificant EKG abnormality –
inverted T waves
• Clinically significant arrhythmia
• Troponin abnormalities—meaning unclear
• ENT:
• Hearing loss –subclinically abnormal >70%,
clinical dx: 10-15% of patients
• Impaired temporal processing
• Ophthal: Optic atrophy - present in 10% of pts
• Fixation abnormalities common (square wave
jerks, ocular flutter)
• Loss of retinal ganglion cells; OCT
FA – Clinical Features
• Endo: Diabetes –10-20%
• >65% Insulin resistance
• Skeletal: Scoliosis
• Corrective surgery required in up to 50%
of patients
• Pes cavus
• GU: Urinary symptoms– 50% of adult
patients
• Urgency, sphincter dysynergia
• Psychiatric: Depression
• Fatigue: Nearly all patients experience
significant fatigue that impacts quality of life
• Cognition: Remains essentially normal
FA – Monogenic condition, Autosomal recessive
1996 – Disease causing gene identified, FXN
GAA
Exon 1
2
3
4
5
L106X
GAA
G130V, I154F
Exon 1
2
3
4
GAA repeats
3-33 – normal
34-65 – premutation
66-1700 - abnormal
5
Primary disease causing mutation is the expansion of a naturally
occurring GAA repeat in the noncoding region of the gene for frataxin
(FXN) - 95% of abnormal alleles. The other 5% of abnormal alleles are
point mutations in the coding regions of the gene.
ONE DOES NOT HAVE TO PUT IN NEW GENE, ONLY TURN THAT WHICH
THERE ON
Mechanisms of FXN silencing by the expanded GAA repeat
New concepts:
Other modifications of
DNA such as
methylation
Progressive
Potentially reversible by
Small RNA molecules
Pandolfo, M. Arch Neurol 2008;65:1296-1303.
Copyright restrictions may apply.
GAA Repeat Size and Age of Onset, Durr et al., NEJM, 1996
•GAA repeat
expansion sizes
correlate with
measures of
disease severity
•GAA repeat
expansions
decrease, but do
not eliminate,
frataxin
expression
•This curve for
1997 looks the
same now.
FRDA
• Pathophysiology
• GAA expansions lead to
gene silencing which leads
to relative lack of frataxin
• Frataxin deficiency leads
to mitochondrial
dysfunction
• Cell selective
mitochondrial dysfunction
leads to clinical
manifestations including
neurological features.
FA TREATMENT PIPELINE – MARCH 2016
PRE-CLINICAL
IND FILED
DISCOVERY
DEVELOPMENT (Investigational New
(Finding Potential
Therapies/Drugs) (Testing in Laboratory) Drug; FDA filing)
Decrease
Oxidative Stress
and/or Increase
Mitochondrial
function
Modulation of
Frataxin
Controlled
Metabolic
Pathways
Frataxin
Stabilizers,
Enhancers,
and
Replacement
Increase
FA gene
Expression
Drug
Discovery
PHASE II
(Human Safety
And Efficacy Trial)
EPI-743
SHP622 (0X1)
NDA FILED
(New Drug
Application; FDA
filing)
AVAILABLE
TO PATIENTS
Shire
RTA-408 – Nrf2 Activator
Reata
Retrotope
dPufas
Nutritional approach
University of Pennsylvania (Philadelphia, PA)
Nrf2 Activators
Ubiquitin
Competitors
PHASE III
(Definitive Trial)
Edison
Ixchel Therapeutics
University of Rome “Tor Vergata” (Rome, Italy)
Frataxin replacement
Chondrial Therapeutics, BioBlast Pharma, IRB Barcelona (Barcelona, Spain)
HDAC Inhibitors
BioMarin
Jupiter Therapeutics & Murdoch Children’s Research Institute, Australia
Resveratrol
Imperial College (London, UK)
Nicotinamide
Horizon
Interferon gamma
RNA-based approach
Gene
Therapy
PHASE I
(Human
Safety Trial)
AAV-based approaches
RaNA, ProQR
Voyager, Agilis, Bamboo, Annapurna, 4D Molecular Therapeutics, IGBMC (Strasbourg, France),
University of Florida
Epigenetic &
FXN expression
Pfizer, Novartis
Frataxin
mimetics
University of Pennsylvania
Mitochondrial
& Pathways
University of Pennsylvania, University of California Davis, & Arizona State University
(Tempe, AZ)
© 2016 Friedreich's Ataxia Research Alliance. All Rights Reserved.
FRDA Therapies
• Conceptual approaches to clinical trials:
• Improve mitochondrial function/antioxidant
• EPI743
• SH622
• Idebenone,
• CoQ
• Retrotope RT001
• Improve bodies reaction to Mitochondrial dysfunction
• Reata RT 408
• Make more frataxin
Ways to make more frataxin
• Turn gene back on
• Inhibit processes turning off—HDAC, methylation
• Use small RNA based therapies to turn on
• Actimmune
• Give exogenous frataxin
• TAT frataxin and similar approaches
• Put in a new gene
• Gene therapy (at least 6 companies)
• Cut out the abnormal gene
• CRISPR technology and others
Pathophysiology of FRDA
• Pathophysiology
• GAA expansions lead to gene silencing which
leads to relative lack of frataxin
• Frataxin deficiency leads to mitochondrial
dysfunction
• Cell selective mitochondrial dysfunction leads
to clinical manifestations including
neurological features
• So what else do we need to test a drug
neurologically?
FRDA
• Measures
• Biomarkers
• Natural history data
• Way to find patients with specific
features
• Funding
• Patient advocacy organization
• Pharmaceutical company support
• CCRN, EFACTS
FA Biorepository (CHOP)
• DNA - >750 samples from patients
• RNA – 300 patients, 150 carriers, 50 controls
• Whole blood - >650 patients, 500 carriers, 200 controls
• Frataxin measurement
• Plasma – 475 patients, 200 carriers, 80 controls
• Serum – 300 patients, 150 carriers, 75 controls
• Buccal cells – 700 patients, 500 carriers, 200 controls
• Frataxin measurement
• Fibroblasts
• Expanding fibroblast lines at Coriell
• M.Napierala - >40 lines growing and establishing iPS
cells
• Muscle biopsy
Neurological measure
Friedreich Ataxia Rating Scale
1. Quantified exam
2. Rate of change over time
know from natural history study
3. Acceptable to FDA in modified
form
Can compare results from clinical trials to
this curve as a control
Typical Anatomically selective measures
• Nerve conduction studies
• Measure large proprioceptive neurons
• Frequently absent in FA patients as soon as symptoms begin
• Do not worsen over time if present
• Somatosensory evoked potentials
• Measure large proprioceptive neurons
• Frequently absent in FA patients as soon as symptoms begin
• Do not worsen over time if present
• MRI scan
• Normal brain early in FA
• Spinal cord atrophy at presentation (reflecting large
proprioceptive neurons)
• Conclusion: typical anatomic measures do not work well in FA
Methodologies for ongoing anatomical
evaluation
• MRI
• Minnesota
• Brazil
• MRS
• Minnesota
• Electrophysiological
• Motor evoked potentials
• Correlate with disease severity in FRDA
Motor Mapping:
Transcranial Magnetic Stimulation
• A safe, well tolerated, noninvasive technique which
uses electromagnetic fields to induce action
potentials in motor neurons
• Assess the integrity of central motor pathways
FDI Muscle
Amplitude
(mV)
TMS pulse
artifact
Time (seconds)
Motor Evoked
Potential
Conclusions
• Many agents coming to clinical trials for
FRDA
• Need collaboration across all groups to
develop novel tests